Drive system and drive control method

1. A drive system, comprising: a battery; a power generation device including: a power generator mounted to a shaft of an engine; and an inverter configured to convert an alternating-current voltage of the power generator into a direct-current voltage; a drive device including: a motor configured to drive a driven component; and an inverter configured to perform bi-directional conversion between an alternating-current voltage of the motor and a direct-current voltage; a switching device including a plurality of change-over switches configured to switch a connection of the battery and the power generation device at both ends of the drive device between a series connection and a parallel connection for connection; a reactor arranged between the battery and the switching device or between the power generation device and the drive device; and a control unit configured to control each of the switching device, the power generation device, and the drive device, wherein the control unit includes processing circuitry to use, when a speed of the driven component is being changed, the switching device to fix the connection of the battery and the power generation device to any one of the series connection and the parallel connection after alternately switching the connection between the series connection and the parallel connection; and to use an efficiency map, in which an efficiency obtained by multiplying a revolution number of the motor and a torque of the motor by an efficiency of the engine, an efficiency of the power generator, and an efficiency of the inverter is defined in advance, to determine a revolution number of the engine based on a battery voltage of the battery.

2. The drive system according to claim 1 , wherein the switching device includes at least three change-over switches as the plurality of change-over switches.

3. The drive system according to claim 2 , wherein the processing circuitry is configured to change an engine revolution number of the engine based on a revolution number and a torque that are required for the motor and on the battery voltage.

4. The drive system according to claim 2 , wherein the processing circuitry is configured to stop, when the speed of the driven component decreases after the battery and the power generation device are connected in series, an operation of the inverter configured to convert the alternating-current voltage of the power generator into the direct-current voltage, and, under a state in which the inverter is kept being stopped, use the switching device to fix connection of the battery and the power generation device to the parallel connection after alternately switching the connection between the series connection and the parallel connection.

5. The drive system according to claim 1 , wherein the processing circuitry is configured to change an engine revolution number of the engine based on a revolution number and a torque that are required for the motor and on a battery voltage.

6. The drive system according to claim 5 , wherein the processing circuitry is configured to increase the direct-current voltage of the power generation device when the battery voltage decreases after the battery and the power generation device are connected in series.

7. The drive system according to claim 5 , wherein the processing circuitry is configured to increase the direct-current voltage of the power generation device when the battery voltage decreases after the battery and the power generation device are connected in parallel.

8. The drive system according to claim 1 , wherein the processing circuitry is configured to stop, when the speed of the driven component decreases after the battery and the power generation device are connected in series, an operation of the inverter configured to convert the alternating-current voltage of the power generator into the direct-current voltage, and, under a state in which the inverter is kept being stopped, use the switching device to fix the connection of the battery and the power generation device to the parallel connection after alternately switching the connection between the series connection and the parallel connection.

9. The drive system according to claim 1 , wherein the inverter configured to convert the alternating-current voltage of the power generator into the direct-current voltage includes a diode.

10. A drive system, comprising: a battery; a power generation device including: a power generator mounted to a shaft of an engine; and an inverter configured to convert an alternating-current voltage of the power generator into a direct-current voltage; a drive device including: a motor configured to drive a driven component; and an inverter configured to perform bi-directional conversion between an alternating-current voltage of the motor and a direct-current voltage; a switching device including a plurality of change-over switches configured to switch a connection of the battery and the power generation device at both ends of the drive device between a series connection and a parallel connection for connection; a reactor arranged between the battery and the switching device or between the power generation device and the drive device; and a control unit configured to control each of the switching device, the power generation device, and the drive device, wherein the control unit includes processing circuitry to control, when a speed of the driven component is being changed, the direct-current voltage of the power generation device to be equal to or lower than a threshold value set in advance, and then use the switching device to fix the connection of the battery and the power generation device to any one of the series connection and the parallel connection.

11. The drive system according to claim 10 , wherein the switching device includes at least three change-over switches as the plurality of change-over switches.

12. The drive system according to claim 11 , wherein the processing circuitry is configured to change an engine revolution number of the engine based on a revolution number and a torque that are required for the motor and on the battery voltage.

13. The drive system according to claim 10 , wherein the processing circuitry is configured to change an engine revolution number of the engine based on a revolution number and a torque that are required for the motor and on the batter voltage.

14. The drive system according to claim 10 , wherein the inverter configured to convert the alternating-current voltage of the power generator into the direct-current voltage includes a diode.

15. A drive control method, which is performed in a drive system including: a battery; a power generation device including: a power generator mounted to a shaft of an engine; and an inverter configured to convert an alternating-current voltage of the power generator into a direct-current voltage; a drive device including: a motor configured to drive a driven component; and an inverter configured to perform bi-directional conversion between an alternating-current voltage of the motor and a direct-current voltage; a switching device including a plurality of change-over switches configured to switch a connection of the battery and the power generation device at both ends of the drive device between a series connection and a parallel connection for connection; and a reactor arranged between the battery and the switching device or between the power generation device and the drive device, the drive control method comprising: using, when a speed of the driven component is being changed, the switching device to fix the connection of the battery and the power generation device to any one of the series connection and the parallel connection after alternately switching the connection between the series connection and the parallel connection; and then using an efficiency map, in which an efficiency obtained by multiplying a revolution number of the motor and a torque of the motor by an efficiency of the engine, an efficiency of the power generator, and an efficiency of the inverter being defined in advance, to determine a revolution number of the engine based on a battery voltage of the battery.

16. The drive control method according to claim 15 , further comprising stopping, when the speed of the driven component decreases after the battery and the power generation device are connected in series, an operation of the inverter configured to convert the alternating-current voltage of the power generator into the direct-current voltage, and, under a state in which the inverter is kept being stopped, using the switching device to fix the connection of the battery and the power generation device to the parallel connection after alternately switching the connection between the series connection and the parallel connection.

17. A drive control method, which is performed in a drive system including: a battery; a power generation device including: a power generator mounted to a shaft of an engine; and an inverter configured to convert an alternating-current voltage of the power generator into a direct-current voltage; a drive device including: a motor configured to drive a driven component; and an inverter configured to perform bi-directional conversion between an alternating-current voltage of the motor and a direct-current voltage; a switching device including a plurality of change-over switches configured to switch a connection of the battery and the power generation device at both ends of the drive device between a series connection and a parallel connection for connection; and a reactor arranged between the battery and the switching device or between the power generation device and the drive device, the drive control method comprising: controlling when a speed of the driven component is being changed, the direct-current voltage of the power generation device to be equal to or lower than a threshold value set in advance, and then using the switching device to fix the connection of the battery and the power generation device to any one of the series connection and the parallel connection.